CA2544382A1

CA2544382A1 - Dual phase steel strip suitable for galvanizing

Info

Publication number: CA2544382A1
Application number: CA002544382A
Authority: CA
Inventors: David P. Hoydick
Original assignee: Individual
Current assignee: UEC Technologies LLC
Priority date: 2003-11-04
Filing date: 2004-05-17
Publication date: 2005-05-26
Anticipated expiration: 2024-05-17
Also published as: PL1682686T3; EP1682686A1; AU2004289949A1; CA2544382C; PL379761A1; EP1682686A4; AU2004289949B2; PL210446B3; EP1682686B1; ES2530066T3; WO2005047550A1

Abstract

Dual phase steel sheet is made using a time/temperature cycle including a soak at about AC1+45~F to AC1+135~F and a hold at 850-940F, where the steel has the composition in weight percent, carbon: 0.02-0.20; aluminum: 0.010-0.150;
titanium: 0.01 max; silicon: 0.5 max; phosphorous: 0.060 max; sulfur: 0.030 max; manganese: 0.8-2.40; chromium: 0.03-1.50; molybdenum: 0. 03 -1.50; with the provisos that the amounts of manganese, chromium and molybdenum have the relationship: (Mn + 6Cr + 10 Mo) = at least 3.5%. The sheet is preferably in the form of a strip suitable for coating in a continuous galvanizing or galvannealing line, and the product is predominantly ferrite and martensite.
The strip may be galvanized or galvannealed at a temperature within thirty degrees F of the temperature of the bath.

Claims

1. Method of making an incipient dual phase steel sheet, wherein said steel sheet has the composition, in weight percent, carbon: 0.02-0.20; aluminum: 0.010-0.150; titanium: 0.01 max; silicon: 0.5 max; phosphorous: 0.060 max; sulfur:
0.030 max; manganese: 0.8-2.40; chromium: 0.03-1.50; molybdenum:0.03-1.50; with the provisos that the amounts of manganese, chromium and molybdenum have the relationship: (Mn + 6Cr + 10 Mo) = at least 3.5%, comprising soaking said steel sheet for 20 to 90 seconds at a temperature within the range of A c1+45°F, to A c1+135°F, cooling said steel sheet at a rate of at least 1°C per second to a temperature in the range 850-940°F, and holding said steel sheet in the range 850-940°F for 20 to 100 seconds.

2. Method of claim 1 wherein said steel sheet is a steel strip and said method is conducted continuously on a steel strip of at least 1000 feet.

3. Method of claim 1 including coating said steel sheet in a vessel of molten galvanizing metal at a temperature in the range 850-940°F before, during, or immediately after said holding.

4. Method of claim 3 wherein the temperature of said steel sheet during said coating is maintained within ~ 20°F of the molten metal temperature to minimize heat transfer between said steel strip and said molten metal.

5. Method of claim 1 followed by cooling said steel sheet to ambient temperature at a rate of at least 5°C per second, and wherein said dual phase is manifested thereafter in a microstructure predominantly of ferrite and martensite.

6. Method of claim 1 including galvannealing said steel sheet and cooling the steel sheet coated thereby at a rate of at least 5°C per second, and wherein said dual phase is manifested thereafter in a microstructure predominantly of ferrite and martensite.

7. Method of claim 1 wherein the carbon content of said steel is 0.03-0.12%.

8. Method of substantially continuously galvanizing steel strip in a galvanizing line including a galvanizing bath, comprising feeding a coil of steel strip having the composition, in weight percent, carbon: 0.02-0.20; aluminum:
0.010-0.150; titanium: 0.01 max; silicon: 0.5 max; phosphorous: 0.060 max;
sulfur: 0.030 max; manganese: 0.8-2.40; chromium: 0.03-1.50;
molybdenum:0.03-1.50; With the provisos that the amounts of manganese, chromium and molybdenum have the relationship (M.n + 6Cr + 10 Mo) at least 3.5%, to a heating zone in said galvanizing line, passing said strip through a heating zone continuously to heat said strip to 1340-1425°F, passing said strip through a soaking zone to maintain said strip within the range of 1340-1425°F
for a period of 20 to 90 seconds, passing said strip through a cooling zone to cool said strip at a rate greater than 1°C per second, discontinuing cooling said strip when the temperature of said strip has been reduced to a temperature ~
30 degrees F of the temperature of said galvanizing bath, holding said strip at a temperature between 850-940°F and within 30 degrees F of the temperature of said galvanizing bath for a period of 20 to 100 seconds, passing said strip through said galvanizing bath, and cooling said strip to ambient temperature.

9. Method of claim 8 wherein the residence time of said strip in said galvanizing bath is 3-6 seconds.

10. Method of claim 8 wherein said cooling in said cooling zone is conducted at 5 to 40 degrees F per second.

11. Method of claim 8 wherein said strip enters said galvanizing bath at a temperature within 20 degrees F of the temperature of said galvanizing bath.

12. Method of claim 8 wherein said strip is passed into said galvanizing bath immediately on discontinuing said cooling.

13. Method of claim 8 wherein said strip is passed into said galvanizing bath near the end of said period of 20 to 100 seconds.

14. Method of claim 8 whereby the galvanized steel strip so made has a predominantly ferrite-martensite microstructure containing less than 5% other morphological constituents.

15. Method of claim 8 wherein the carbon content of said steel strip is 0.03-0.12 weight percent.

16. Method of claim 8 wherein said steel strip is galvannealed prior to cooling to ambient temperature.

17. Method of making a galvanized steel strip having a predominantly martensite and ferrite microstructure, wherein said steel has the ingredients, in weight percent, carbon: 0.02-0.20; aluminum: 0.010-0.150; titanium: 0.01 max;
silicon: 0.5 max; phosphorous: 0.060 max; sulfur: 0.030 max; manganese: 0.8-2.40; chromium: 0.03-1.50; molybdenum:0.03-1.50, comprising soaking said steel strip at A cl+45°F, to A cl+135°F, for at least 20 seconds, cooling said strip at a rate of at least 1°C per second, passing said strip through a galvanizing vessel for a residence time therein of 2-9 seconds to coat said strip at any time while holding said strip at 895°F ~45°F for 20 to 100 seconds, and cooling the strip so coated to ambient temperature.

18. Method of claim 17 including galvannealing said strip prior to cooling to ambient temperature.

19. Method of claim 17 wherein said strip is within 30°F of the temperature of the galvanizing vessel during said residence time therein.

20. Method of claim 17 wherein said strip is within 20°F of the temperature of the galvanizing vessel during said residence time therein.